Apparatus for recovering metal from ore



Fell 1, 1944` E.v RNEROLL APPARATUS` FOR RECOVERING METAL FROM ORE Filed Marqh 9, 1942 4 sheets-sheet 1 irl' l lll A A l INVENTOR` A 5 l ArroRA/EY.

Feb. 1,- 1944. A Rl-VERQLL APPARATUSr4 FOR REcovERING vMETAL FROM RE Filed Mai-ch 9, 1942 `4 sheets-sheet s- Pff@ i L o N e @W ,N 7

Feb. l, 1944. E. RIVERQLL 2,340,346

APPARATUS FOR RECOVERI'NG METAL FROM ORE Filed March 9, 1942 4 Sheets-Sheet 4 /Wf'yu 12.`

Patented Feb. l, 1944 l APPARATUS Fon nEcovEmNGw ETAL `FROM ORE p i A Elfcgo Riveroll, Hermosa Beach, Calif. Application March 9, 1942, Serial No. 433,861

(Cl. 26S-10) e `12 Claims. This invention relates to apparatusjfor use in `,the recovery of metal from ore, and particularly to apparatus for use in the reduction and recovery of a metal from an ore containing such metal in oxidized condition, for example, in the form of one or more higher oxides.

The apparatus is adapted particularly for the reduction and recovery of iron or manganese from ores containing one or more of these metals `in oxidized form, and more particularly from ores containing one or more of the higher oxides of such metals; for example, for the recovery of an improved apparatus for use in reducing a metal from. a relatively high state of oxidation, to a lower state of oxidation, by` contact at a suitably elevated temperature with a hydrocarbon iron from ores containing hematite (FezOa) or magnetite (FesOr), or for the recovery of man.-

ganese from ores containing pyrolusitel (MnOz), hausmannite (Mn'iO-i), or

manganite (Mn2Os.H2O)

or from minerals commonly referred to as wad, which are impuremixtures containing higher oxides of manganese. The apparatus may also be employed however, forthe reduction and recovery of other metals from oxide ores.

This application is a continuation in part `of my Patent Number 2,310,258, February 9, 1943, for Process and apparatus for recovering manganese from ore. n

The principal object of the invention is to provide an apparatus for the above purposes, in which a hydrocarbon fluid (i. e., a hydrocarbon gas or liquid, or both) is used as the principal agent required for the reduction of the metal from its original oxidized stateto the metallic state, in which the treatment of the ore is conducted in a plurality of sccessive stages, and in whichthe conditions in the several stages may be maintained in such manner, that the heating of the ore and the reduction of the metal are accomplished eiiiciently and economically. In this connection, a particular object is to obtain a high degree of economy and freedom from operating diiliculties, by providing an apparatus for carry-4 ing out the successive stages in different types of furnaces or heating units, the characteristics of each furnace and the combined `arrangement, thereof being such,that the furnace in each stage is particularly adapted to accomplish the treatment desired in that stage.

A further object of the invention, is to provide an apparatusin which the reduction of the metal does not require the introduction of any solid reducing agent, although,` as will be explained, some solid reducing agent may if desired be used in the last stage of the process.

A further object of the invention, is to provide fluid, and for completing the reduction of the metalto metallic state, by heating to a higher temperature in the presence of carbon deposited in the ore during the contact thereof with the hydrocarbon fluid.

Another object of the invention is to provide an apparatus `for the production of steel from ironores, without requiring the ore or the reduced metal to be brought into contact with airl e or other nitrogen-containing gas, at a temperature sufficient to cause absorption ofnitrOgen, l u `thus permitting production of steel substantially free from nitrogen. 1

`Another `object is to provide an advantageous type of furnace for use in the reduction of a metal oxide in an ore, by contact with a heated hydrocarbon fluid in an externally heated enclosed reducing chamber. s l

`The complete 'apparatus for accomplishingthe l above and other objects in accordancewith the present invention, is adapted for subjecting the ore to `treatment in at least three successive and separate stages. In the rst stage the ore. is

heated, principally forthe purpose of drying and preheating it to a suitable temperature for reduction, and some reduction may also be effected inthis stage. The heating apparatus used in this stage comprises a furnace preferably ofthe rotary kiln type, provided with an ore preheating chamber in Vwhich the ore is `brought into direct and intimate contact withhot gases,` and is relatively free to expand. 'I'his drying and preheating furnace is preferably heated at least in part, by combustion of combustible gases from the subsequent reducing stage, and by residual heat of the combustion gases usedior heating the ore in the reducing stage, as described more fully hereinafter, andif necessary, additional gas or other fuel may be suppliedand burned in suf--` lcient amount to maintain the desired temperature.

In an intermediate stage, the dried and preheated ore is subjected to contact with a pre heated hydrocarbon iiuid at a temperature suf-` ficient to cause partial reduction of the metal,

for example, to cause reduction thereof 'to a.A lower oxide, and partial reduction thereof to the metallic state,` and to alsocause deposition of carbon in the ore. The apparatus used in this intermediate stage, is arranged: to provide for indirect heating of the ore in one or more enclosed reducing chambera'and provided with means for introducing heated hydrocarbon fluid into contact with the ore at a plurality of suitably distributed positions in said chamber or chambers. According to a preferred embodiment o1' the apparatus, this intermediate onreducing stage. is carried out in two successive furnaces, which may be referred to as auxiliary and main reducing' furnaces respectively, each providedwith an enclosed chamber through which the ore is passed, and is brought into contact with the hydrocarbon fluid, the auxiliary and main reducing furnaces being provided with means for sunplying heat to the ore therein. preferably by direct contact with hot gases in the auxiliary fur.- nace, and by indirect heating in the main furnace. In this embodiment the irst or auxiliary reducing furnace. rnay in some cases be also used to complete the preheating of tane ore to suitable temperature for reduction. or the preheating of the ore may be conducted wholly in the saine furm nace which is employed as the auxiliary reducing furnace. This intermediate or reducing stage may. as a further alternative. be conducted in a single furnace. as illustrated in one of the einn bodirnents hereinafter described.

In the final stage, the ore is subiected to iurther heating in the presence of suiiicient carbon or other solid reducing agent. and at sufcientlv high temperature to complete the reduction oi' the metal to the metallic state and to cause fusion thereof, and the formation of a slag containing the gangue constituents of the ore. This final reducing and smelting operation is carried out in an enclosed chamber, in which a reducing atmosphere is maintained. and from which air is excluded, and the furnace used in this stage is preferably an electric iurnacavoi either the arc or induction type.

In addition to the furnaces used in the several stages above described. the apparatus further comprises means for preheating the hydrocarbon fluid used in the intermediate or reducing stage. Means are provided for conducting the preheated reducing fluid from the fluid preheating apparatus and introducing it into contact with the ore in the enclosed chamber or chambers of the furnace or furnaces in theinterrnediate reducing stage. also prefer to provide means for conducting hot combustion gases from the iiuid preheating apparatus, to a suitable `furnace chainn ber in heat exchange relation to the enclosed reducing chamber, or one of the reducing charnbers in the intermediate stage, in order to utilize the residual heat of such gases.

With the above-stated and other objects in View, which will appear asthe description proceeds, the invention resides more particularly in the novel construction, combination and arrangement of parts, of which certain embodiments are specically described herein and illustrated in the accompanying drawings, but it is to be un derstood that the latter are merely illustrative of certain embodiments of the invention, and that the actual needs of practice and manuacture, :may require certain mechanical variations from the embodiments shown. It is, therefore, not inten-ded to limit the invention to the 'disn closure thereof herein ilustrated, but rather to the scope of the subioined claims. v

Referring to the accompanying drawings:

Fig. l is a partly sectional side elevation oa preferred forni oi complete apparatus, in accord ance with this invention, in which the treatment titi acconto of the ore is conducted in Ifour successive furnaces;

Fig. 2 is a horizontal section on line 2--2 in Fie. 1;

Fig. 3 is a vertical section on line 3-3 in Fig. 1;

Fig. 4 is a vertical section on a larger scale of the main reducing furnace, and part of the aux iliary reducing furnace shown in Fig. 1;

Fig. 5 is a fragmentary vertical section of the lower portion of the mainv reducing furnace, taken Fig. 7 is a vertical sectional view of one of the l pipes or nozzles, through which reducing uid is introduced into the ore in the main reducing furnace;

Fig. 8 is a vertical section of the upper portion of a modied form of furnace, that may be substituted `for the auxiliary reducing furnace of Fig. l, in case it is desired to utilize this furnace for drying and preheating the ore, and to omit the rotary kiln shown in Fig. 1;

Fig. 9 is a partly diagrammatic side elevation of another form of complete apparatus in accordance with the invention, with certain parts broken away;

Fig. 10 is a horizontal section on line IDI-0 inFig. 9;

Fig. 11 is a vertical section on line l l-Il in Fig. 9; and

Fig. 12 is a vertical section, on a larger scale, of the reducing furnace shown in. Fig. 9.

The apparatus shown. in Fig. 1 comprises a rotary kiln l, an auxiliary reducing furnace 2, a main reducing furnace 3, and an electric furnace t.

The rotary kiln i is inclined downward from right to left, and may be provided with any suitable conventional means, not shown, for rotating the kiln about its longitudinal axis. The upper and lower ends of the kiln extend into and communicate with housings 5 and 6, respectively, and the kiln is provided at its lower end with burner means l, adapted to maintain a flame directed into the interior of the kiln which constitutes the ore preheating chamber, and is provided at its upper end with a stack 8 for discharge of waste gases, and with means such as feed spout 9, for supplying ore in crushed or suitably divided condition into the upper end of the kiln. Burner 'l is provided with a fuel sup ply pipe il, having means such as valve Il' for regulating the supply if fuel, and with an opening as indicated at l2, for admission of air t0 the burner, the supply of air being regulated in any suitable manner.

A suitable conduit i3 connects the lower end of housing t, tothe upper end of the auxiliary reducing furnace 2, for conducting the ore from the kilyn i to furnace 2, and for conducting gaseous 'products from furnace 2 to kiln l. `Said conduit is preferably centrally located with respect to furnace i2.

Referring to Figs. l and fi, the auxiliary reducing furnace E comprises a bottom Wall l5, a domeshaped top wall i6. and a side wall il preferably of cylindrical shape, formed of steel or other suitable metal. The side and bottom walls are lined with refractory brick as indicated at I8 and iii, and an inner conical bottom wall 2l is preferably provided, iorrning the bottom of an orereceiving chamber 22 within the furnace, and protecting the refractory brick i9. Top wall I6 is provided .with a central opening I4, through which the conduit I3 communicates with cliamber 22. A layer of heat insulating material is preferably provided vbetween the refractory linving I8 and` side Wall I1.` The top wall I6 and The mainreducing furnace Scomprises an inner housing `3I and an outer housing or shell 32, the construction of whichis best shown` in Figs. 2 and 4. The inner housing includes a side wall 33, formed as a vertically extending cylindrical shell, a top wall 34, and aconical bottom wall 35, defining therewithin a completely enclosed vertically extending reducing chamber` 36, from which air is excluded substantially completely, and in which a vertically extending body of orc is continually maintained during operation of the apparatus. Said reducing chamber` is provided with means hereinafter described, for admitting hydrocarbon fluid thereto under suitable pressure, and is preferably provided with means for maintaining a pressure in the reducing chamber slightly greater than atmospheric pressure. l

The outer housing 32 is also cylindrical in` shape, and extends throughout the major portion`of the height of the inner housing, to define an annular furnace chamber 38 surrounding the` reducing chamber 36 throughout the major portion of its height. The outer housing is shown as comprising a cylindrical side wall or shell 3,9, and a bottom wall 4I constructed o f steel or other suitable metal, the side and bottom walls being lined with refractory brick as' indicated at 42 and 42, and the side wall being preferably also provided witha layer of heat-insulating material indicated at 43. Adjacent the lower end of the outer housing are four burner openings 44 spaced 90 apart, in which are mounted burner means such `as nozzles 45 to which combustible gas or other fuel is supplied, said burner meansserving to supply hot combustion gases to the furnace chamber 38. l The outer housing also includes a top wall 46 closing the upper` end of said furnace chamber. The furnace is provided with an outer top wall 41 above andspa-ced from tcp walls 34 and 46, and the space therebetween is filled withisuitable heat-insulating material as at 48.

Suitable means are provided for conducting ore from the chamber 22 `of furnace 2 to the reducing chamber 36 of furnace 3. `For this purpose I have shown a screw conveyer or feeder 50, mounted within a trough or housing 5 I, into which the ore falls through a central opening 52 in the bottom of chamber 22. `A vertical chute or conduit 53, extends downward from conveyer housing 5I, to a central opening 54, at the upper end l of chamber 36.` The conveyer is shown as provided with a bevel gear 56, by means of which it may be rotated continuously or intermittently, to convey ore from opening 52 to the upper end of chute 53. I prefer to operate with a continuous movement of ore through the sytsem, but in order to permit lintermittent operation if desired, I

have` provided a sliding gate 51 in chute 53, which may be moved to open or closed position.`

Suitable means are provided for conducting hot combustion gases from the annular chamber 38 of furnace 3, into the ore chamber 22 of furnace 2, preferably at ajplurality of positions in of chamber 38. At their upper ends these pipes extend upward through the refractory lining I 8 of furnace 2, to positions above the mid-height of `chamber 22, and preferably near `the upper end thereof, where they open into said chamber; The upper ends of said pipes are shown as bent' inward as at 59,'so as to deliver gases in a generally horizontal inward direction into the chamber, and the extreme inner ends are shown as inclined outward I and downward as at 59', to prevent ore from entering the pipes. l l

I also provide means for conducting gases from` the upper end of reducing chamber 36 to the pre-` heating furnace, preferably through the chamber 22 of `furnace 2. 'I'he means` for this purpose is shown as including a pipe 6I, opening at its lower end into the upper end of `the reducing chamber, and connected at itsrupper end to one` of thepipes 58, as by pipe 62. `It will be understood of course, that similar connecting pipes'62 may also beprovided, for` connecting pipe 6I to one `or more of the other pipes 58.

anddistributing the iiow of gas and for maintaininga `suitable pressure within the reducing: chamber 36. It will of course be understood,

that when gate 51 is open to permit downward movement of ore, a large portion of the gases from chamber 36 will pass upward through chute 53, and throughthelore'body in chamber 22,

but such ore bodyimposes sufficient resistance to flow of gas, to maintain a slight super-atmospheric pressure in chamber` 36 under these conditions. I-

The electric furnace 4 may bean arc furnace, .l

or induction furnaceof a conventional air-tight type, adapted to exclude air from the interior` thereof, and provided with means for electrically heating the partially reduced ore therein to a sufficiently high temperature, for completing the reduction `and for smelting the resulting metal. This furnace is also `provided with means for discharge of' molten metal and slag, as indicated at 68 and 69,` the actual construction and arrangement of such discharge means and other parts of the furnace, being dependent upon the particular type of furnace employed. The specific construction of this furnace is not shown, and further description thereof is believed unnecessary. I may use any one of a numbervof specific types, whose construction and operation is well known in the art.

For delivering'ore from the bottom of the reducing chamber 36 to the electric furnace 4, I Y

have provided a short screw conveyer or feeder 1I, mounted within a trough or housing 12, into which the ore falls through a central opening 13 at'the bottom of chamber 36. Conveyer `1I f is similar in construction and operation to the conveyer `5,0 above described, and an inclined chute 14 leads from conveyer housing 'I2 to theupper end offurnace 4, saidv chute being pro vided with a sliding gate 15 or other suitable I means, movable to position to open and close the the upper portion thereof. `For this purpose I i chute to movementof ore. Thus, the ore may be delivered continuously or intermittently into g The lowerend' of chute 14 l the electric furnace. is connected to the electric furnace, in such inanner as to communicate with the 'interior there of, in a substantially air-tight mannen How- Inaddition, I `have also shown anotherpipe 63, connecting pipe ever, in order to positively prevent leakage of air into furnace 4,- chute 14, or reducing chamber 36, it will be understood that the gasestherein are normally maintained at a slight superatmospheric pressure. In case the lower end of chute 14 is disconnected from the furnace for any reason during operation, the gate may be closed, to further prevent access of airl into the reducing chamber 36. Y

The apparatus is also provided with means for preheating hydrocarbon fluid, and with conduits or pipes for introducing the preheated fluid into the reducing chamber 36 of furnace 3, and preferably also into the ore-receiving chamber 22, of furnace 2. This preheated hydrocarbon fluid is preferably introduced into chamber'36 at a plurality of positions, intermediate the height ofthe heating chamber 38 (i. e., intermediate the height of the externally heated zone within the reducing chamber), and into chamber 22 at a plurality of positions adjacent,r but somewhat above the lower end thereof.

The fluid preheater is indicated at 8|, and isv shown as comprising a cylindrical furnace housing provided with a refractory lining 82, defining a combustion chamber 83. Suitable burner means 84 are provided at one end of the combustion chamber, to which combustible gas or other fuel is supplied, for maintaining a flame directed into the combustion chamber. A plurality of heating coils 85 areprovided, extending longitudinally within the combustion chamber 83, and supported on suitable supporting means 86. 'I'he furnace and the heating coil means therein are preferably so constructed and arranged, that any one or all of the coils may be readily disconnected and removed from the furnace, for the purpose of cleaning out carbon or coke deposited therein, and replaced by clean coils. I prefer to provide a separate supply line ,81, for supplying hydrocarbon fluid to each of the heating coils, said supply lines being connected to any suitable source of supply of hydrocarbon fluid under pressure, and being veach provided witha separate valve 88, for controlling the admission of fluid to the corresponding coil 85. In the particular arrangement shown, seven heating coils are provided, from which the preheated fluid is conducted to chambers 36 and 22, by separate pipes or conduits, as described hereinafter. A

A flue 9| communicates with the combustion chamber 83 at the end opposite the burner 84, for

conducting hot combustion gases, after giving up part of their heat to the fluid within the coils, into the lower end of the furnace chamber 38 of furnace 3. Said flue is shown as connected at its upper end to` an annular housing 32, which surrounds the conical lower portion 36 of the inner housing 3|, and communicates with the charnber 38 through a plurality of angularly spaced openings, as indicated at 93 in Fig. 2. Flue 9| may if desired, be provided Withsuitable damper means for regulating the draft at the burner 34.

The means for introducing preheated hydrocarbon fluid into the reducing chamber 36, is shown as comprising eightl pipes 85, which extend up through the bottom of the inner housing 3|, and open into chamber 36 at their upper ends, at positions between the axis and periphery of said chamber, and equally spaced about the axis thereof. As illustrated particularly in Fig. 7, each'of the pipes 95 is provided with a cap 96, extending over` the upper end thereof, and with .3.. plurality of openings 91 below said cap, in order to prevent 'the ore from entering the pipe,

while permitting outflow of the reducing fluid into the ore body. Referring to Fig, 4, it will be seen that each of the pipes 95 communicates with the interior of the reducing chamber 36, within the lower portion of said chamber, and at a level somewhat above the bottom of the surrounding furnace chamber 38. The pipes 88 themselves are not seen in Fig, 2, but the positions thereof are apparent from the positions of the caps 96 shown in that figure.

'I'he means for supplying hydrocarbon uid to chamber 36, also comprises a centrally located vertical pipe 98, extending from a position somewhat above the bottom of the chamber upward, to a position preferably somewhat above the mid-height of the chamber, said pipe being closed at its upper end as indicated at 99, and provided with spaced partition members |0| and |02, dening two separate chambers |03 and |04 within the pipe. Two sets of outwardly projecting nozzles or orifice members |05 and |08, are provided at dierent levels intermediate the height of chamber 38, communicating respectively with the lower and upper chambers |03 and |04, and opening outwardly into chamber 36. I have shown four such nozzle members in each set, spa'ced 90 apart around the pipe, and

these members are preferably inclined down- The means for introducing fluid from the preheater 8| linto the ore chamber 22 of furnace 2, is shown as comprising four pipes ||2 extending up through the bottom wall I5, and through the conical wall 2| into the lower portion of said chamber, and each of said pipes is provided at its upper end with a nozzle member I3, directed downward and inward, for delivering the fluid into the ore body in a downwardly inclined direction, while preventing the ore particles from entering these pipes'. Nozzles ||3 are spaced 90 apart around the chamber, and communicate with the lower portion thereof, at positions somewhat above the lower end of the chamber. Referring particularly to Figs. 1, il and 6, the pipes 95, |01, |08 and ||2, are shown as extending downward to a position near the rear end of preheater 8|, and connected in pairs to pipes ||6, which extend through the rear wall of `the preheater 8|, and are connected to the respective heating coils 85. The eight pipes. are connected, in four groups of two each, to four of the pipes H6; the pipes |01 and |08, are connected to one of the pipes H6; and the pipes ||2 are connected in two groups of two each, to the remaining two pipes H6. Each of the pipes 95, |01, |06 and ||2, is preferably provided with a separate valve ||1, to provide for separate regulation of the flow of fiuid through the several pipes. Although no ore is shown within the chambers 22 and 36, it will be understood that during normal operation of the apparatus, a body of ore is continually maintained in each of these chamdicated for example, by the dotted lines at A and B in Figs. 1 and 4, respectviely. The ore level A in chamber 22, is considerably above the nozzles ||8, but is somewhat below the upper ends 58 of thevgas conducting pipes 58, while the ore level B in chamber 80, is considerably above the upper ends oi pipes 85, and somewhat above the upper set of nozzles |06. The ore particles are of such size as to form a pervious bed through which the introduced fluid, may pass without disturbing the ore particles, and Without undue resistance to circulation of gas or other iiuid.

In the operation of the above described apduced through nozzles H3, which serves to eilect partial reduction of higher oxides of themetal or metals present therein, as described more fully paratus, the ore in suitably crushed or divided l condition, for example, in the form of particles of about one-half to three-quarters inch average diameter, is introduced into the upper end of the preheating chamber in rotary kiln I, and is heated therein by direct contact with hot combustion gases from burner 1, and alsoby hot gases entering thekiln through conduit I3 from furnace 2. In case these latter gases contain combustible constituents, as is usually the case,

a suiiicient amount of excess air may be admitted at ork adjacent the burner 'I lfor combustion of ythese constituents, to assist in heating the ore The ore,`

passing through the rotary kiln I. which may ,for example be one of the above-mentioned ores containing a higher oxide of iron or manganese, is thus heated in the kiln to thoroughly dry it, and to preheat it in the iirst stage of vthe treatment, preferably to a temperature substantially equal to or closely approximating` the temperature to be maintained 'in the subsequent reducing stage. -In general, I prefer to heat the ore in this `ilrxst stage toa temperature' the chamber 86, an'd heat is supplied thereto in?V directly through the `walls; of the inner housing ore particles to takeiplace'in the iirststage, Iv

eliminate the possibility of the orej'hecomingv tightly jammed or wedged in 'the .reducing chamber. as frequentlyoccurs. if it is attempted to heat the ore from' a materially lower tempera- 4 hereinafter. In case the ore has not been heated to the necessary temperature for reduction when it enters chamber 22, the heating thereof to the required temperature may also be completed in this chamber, by contact with hot combustion gases from chamber 38, and with the hot hydrocarbon Huid itself.

From the bottom of chamber 22, the ore is discharged continuously or intermittently and introduced into the top of the reducing chamber in furnace 3, by operating screw conveyer 50, with gate 51 in open position. A vertically extending bodyv of ore is thus continually maintained within 3|, from the hot combustion gases in thesurrounding furnace chamber I8. Hot combustion gases from the iluid heating unit 8| are introduced into the bottom oi chamber 38, through flue 8|and housing 82, and the hot gases passing through the housing 92 also serve to heat the ore in the lower conical portion of chamber 88. :Additional hot combustion gases are also Asupplied to chamber 38 by the combustion ofg'as or other fuel at burners 45.

Heated hydrocarbon iiuidifrom coils of heat` er 8| is delivered through pipes 85 and nozzles |05 and |06, into direct and intimate contact with the ore in chamber.

For best results in the treatment of iron or manganese ores, `the ore within the `reducing Achamber 88, and also in the lower portion at least of chamber 22 of furnace 2, is maintained at a.

temperature between about 650 and 800 C., alfthough in some cases satisfactory results are obtained at temperatures as low as about 400 C. or asl high as about 900 C., and higher or lower temperatures may be found desirable in the treatment of other ores.

It will bel understood that the uid preheater ,8| is operated continuously. and that hydrocarbon fluid is continuously supplied to the heating coils 85 thereof, in which it is heated to a tem-y perature atleast approximating. andpreferably i somewhat above (for example.. aboutr -fto C. above) the temperature ,of-the'oreinthe ture to the temperature required Vfor reduction,` at a position substantially below the upper surl face of a relatively stationary body of ore, where the ore particles are not free to expand and consequently tend to become jammed or stuck due to the pressure created by sulting from such heating.

The heating of the ore to the above-mentioned temperature and the resulting expansion in the.

rst stage, also produces Iracturing, splitting, or

cracking or the ore particles (without appreciable disintegration or breaking upc! `the parti-,- cles), and the resulting cracks or fissures serve to promote effective contact of the reducing nuid with the material in the interior of the particles in the second Stage.

thermal expansion ref y furnaces 2 and l.

drocarbonl gas, -if av supply thereof is available.

The term hydrocarbon `gas is understood tri-inl? clude either natural gas, which generally con siste principally of methane with some ethane or other higher hydrocarbons, or oil gasvor other The hydrocarbon uld employed'x'nay beeither I a gas or a liquid., In general, I prefer tousea hyg manufactured gascontaining hydrocarbon con- The rotary kiln is preferably operated contin-`v uously, and the dried and heated ore is discharged from the lower end thereof through conduit I3, into the chamber 22 of furnace 2.

' In chamber 22 the ore is kept heated by means n of hot combustion gases introduced through pipes 58 from the burners 45, and is also broughtinto contact with preheated hydrocarbon iiuid introstituents, produced by thermal vcracking or decomposition `or' liquid petroleum productaand' `generally containing hydrogen and carbon :incur--` i oxider in addition to methane-and other hydrocarbone.

i Where an adequate supply of hydrocarbongas is'not'available, l' may use a hydrocarbon liquid. such as,"for example,y fueloil, gas oil, or other liquid petroleum product or traction. However.'

.as noted above; the huid is heated to a relatively high vtemperature in coils 850i heater 8I,`Ior ex-` l` amp1e,to a temperature of about 500 C. or above,

and preferably about 750" 1C.` or higher. Practically all liquid petroleum products, upon being heated to such temperatures, are completely con- -verted to the form of gas, either by direct vaporization or by thermal decomposition, or both, to

rhs term hydrsrben'num is therefore used herein to include either ages or 'a liquid or amix turel thereof, as lwelljastoinclude material originallyintrodu'ced- 'fli'duid form and converted, by heatingV to gweous formi-g'Y Furthermore, refersumed in the reduction of the metal oxide or oxides, a portion of the carbon so formed is `ie I posited upon and throughout the ore particles ences herein to the of such a fluid, will be g understood to include. heating accompanied by partial or complete conversion of liquid to gas, in

case such conversion occurs. I

The 'hydrocarbon fluid, already at high temperature, is brought into intimate contact with the ore. both in the lower portion of chamber 22 in furnace 2, and also in the reducing chamber 38 i of furnace 3, which together constitute Athe reducy ing'zone of the intermediate stage. The valves lil may be .so/adjusted as to provide for maintaining the most desirable conditions of pressure, and rate of introduction of hydrocarbon fluid, at thedifferent positions Vof introduction thereof. This hydrocarbon uid reacts, at the elevated temperature, with the higher oxide or oxides of the metal or metals present in the ore, reducing the same in part to the metallic state, and in `part to a lower oxide or oxides, such as FeO in a the treatment of an ore containing a higher oxide of iron such as hematite, or MnO in the treatment of an ore containing a, higher oxide of manganese such as pyrolusite. The hydrocarbon fluid is also at least partly decomposed upon contact with the ore at the existing temperature, resulting in the formation ofgaseous products including hydrogen, and of solid carbon.

The reduction of the metal oxides in the ore probably results, at least principally, from the reaction thereofrwithn hydrogen and carbon so formed, and these reactions also result in the formation of water vapor and carbon monoxide,

'as gaseous reaction products. Some reduction of the metal [oxides may also take place, by direct reactlon'thereof with the hydrocarbon iluid itself. Some formation of carbon may also occur as the result-of. reaction 0I the reduced metal with carbon lmonoxide formed by the above reactions, or

vwith carbonmonoxide present in the hydrocarbon gas introdueedinto the reducing zone.

The gaseous: reaction products produced in chamberlsre discharged from the upper end 'l vtlie'rco'fj',antiL are delivered through conduit 53 intochamber, 22, or through pipe 6i into the up- .perrportion `of chamber 22 or into conduit 53, as

described above, and dependent upon adiustment of valves and 35 and gate 51. Any gases passing through conduit 53 are brought into further contactv with ore therein, and in the lower portion of chamber A22, to cause additional reduction.

The gaseous products from chamber 22 of furnace 2 are delivered through conduit I3, into the lower end of the rotary kiln l. In addition to the hot combustion gases supplied to chamber 22 through pipes 58, these gases also include the gaseous reaction products such as carbon monoxide and hydrogen formed in chambers 36 and 22, and possibly some residual unreacted conof manganese ore. i

and remains intimately and uniformly dispersed therein, either in the form of free carbon or Vchemically combined with the metal. The condiduced to the ,metallic state, and the remainder thereof is reduced to an oxide or oxides lower than originally present in the ore, for example. FeO in the case of iron ore, or MnO in the case If the gas used is oi' relatively low hydrocarbon content, as when oil gas or other manufac tured gas containing considerable hydrogen or carbon monoxide or both is used, it may be found desirable to enrich the hydrocarbon content by introducing a hydrocarbon liquid, either with the gas or separately, in order to increase the deposition of carbon in the ore. If desired, hydrocarbon liquid may be supplied through some of the heating coils 85, and hydrocarbon gas .through others. For example, I may supply hydrocarbon liquid to the coil or coils connected to some or all vof the nozzles |l3 in chamber 22, and hydrocarbon gas to the remaining coils.

The partially reduced ore, with the carbon deposited therein, is delivered continuously or intermittently from the bottom of chamber 34E into the electric furnace 4, by operating screw conveyer 1l with gate 15 in open position. In this final stage of the process in the electric furnace, the ore is heated in the presence lof suflicient carbon or other solid reducing agent, to complete the reduction of the metal to the metallic state. and to a sufficient temperature to complete such gangue constituents being also fused to form a slag. The temperature required in this stage willfof course, depend upon the metal or metals present in the ore. iron ore, I may operate the electric furnace at a temperature of about 1300 to 1650 C., and in the lease of manganese ores, ata temperature of about 1200 C. to 14.00 C.' In case the amount of carbon contained in the ore discharged from furnace 3 is insuicient to complete the reduction of the metal in the electric furnace, and to provide such additional carbon as may be desired in the finished metal product, I may add the required amount of .additional carbon to the charge in the electric furnace, preferably in the form of crushed or powdered coke. In general, however, and under preferred conditions of operation, the amount of carbon contained in the ore delivered to this furnace is sufficient for these purposes.

Carbon monoxide is Iproduced by the reaction of the carbon with the metal oxide or oxides in the electric furnace, and serves to maintain a reducing atmosphere therein and to prevent inward leakage of air into this part of the system.

stituents of the hydrocarbon fluid. As has been The gases so produced may be vented from the For example, in the case of nace, and the formation of a slag that separatesl readily and completely from the molten metal, and any such fluxing agent is preferably added to the ore delivered into the rotary kiln I, so as to be dried and heated along with the ore.

When the reduction and smelting is completed inthe electric furnace, the slag and molten metal are withdrawn, either separately or together, and the metal may be solidified in the form of ingots or cakes, in well known manner.

One advantage of the apparatus is that it makes possible the production of steel substantially free from absorbed nitrogen, due to the absence of contact of reduced metallic iron with air, or other nitrogen-bearing gas at a temperature sufficient to cause absorption of nitrogen. Air is completely excluded from the electric furnace 4 in which thefusion of the iron and formation of steel take place, and is also excluded from the zone or zones in which the reduction by contact with-hydrocarbon fluid takes place, that is, in the lower portion of chamber 22 and in chamber 36. Furthermore, the temperature in chambers 22 and 36 is insufficient to cause apprecciable absorption of nitrogen by metallic iron, even if some nitrogen is present, for example as an impurity in the natural gas or other hydrocarbon fluid.

In some cases I may prefer to use a simplified form of apparatus, in which the rotary kiln l is omitted and the crushed ore is charged direotly into the chamber 22 of furnace 2, and the preheatingl and drying of the ore is conducted in the upper part of said chamber. In order to obtain combustion in the upper part of chamber 22 for this purpose, air may be introduced through one or more of the pipes 58, as by simply venting one or more of these pipes to the atmosphere. However, `I `prefer in such cases to provide other means for introducing combustion air, and means for charging ore directly into this furnace, and the construction of the upper part of furnace 2 may therefore be modified as indicated in Fig. 8.

Referring to Fig. 8, the upper part of this modified furnace is indicated at 2', having a chamber 22 corresponding to chamber 22 in Fig. l. A central opening I4 atv the top of the furnace, is connected directly to a stack |25 provided with a damper |26. A suitable number of charging openings |21 are provided in top wall I6'. Each of these charging openings is shown as provided with a pivotally mounted door |28 movable to wide open position for charging ore into the furnace, and to closed or partly closed position over openings |21. The construction of furnace 2' is in other respects the same as described in connection with furnace 2, and it is similarly provided with pipes 58 and'll2 as shownin Fig. 4, for introducing hot combustion gases and hydrocarbon fluid into the upper and lower portions respectively of chamber 22.

When using this modified type of furnace, the rotary kiln and its appurtenant parts are omitted, and the remainder of the apparatus is constructed and arranged in the same manner as described above, and illustrated in Figs. l through 7.

By maintaining the doors |28 in partly open position during normal operation, combustion air is drawn downward through the openings |21 by the draft, and toward the top of the ore` body, in sumcient amount to support combustion of combustible constituents present in the gases rising through the ore body, and also of combustible gasesfrom chamber 36 of vfurnace 3, which may if desired, be delivered into the upper portion of chamber 22 through one or more pipes 58 shown in Fig. 4, as described above in connection with that figure. This combustion takes place at the top of and immediately above the body of 4ore in chamber 22', and 'serves to dry and preheat the ore within the upper portion of such ore body. At'this position, the ore is quitefree to expand on heating, without causing any tendency to become jammed and prevent free downward movement of the ore, as would be the case if Ithis heating occurred at a lower position in theore body.

In the operation of this form of apparatus the ore is charged into furnace 2', and is dried and heated in the upper portion thereof to a suitable temperature such as described above in connection with rotary kiln and then passes downward through this furnace, through furnace 3, and into the electric furnace 4, the process being conducted in substantially the same manner as previously described. Additional combustion air may, if desired, be admitted through some of the nozzles ||3 in the lower portion of the iurnace 2'. For example, a pair of pipes ||2 leading to two diametrically opposite nozzles |l3 (see Fig. 4), may be connected to one of the heating coil pipes H6, and air may be introduced through the corresponding heating coil instead of hydrocarbon fluid. The air so introduced is preheated in passing through the heater 8|, and is delivered throughsaid nozzles ||3, and used to support combustion of combustible constituents present in Ithe lower portion of chamber 22', such combustible constituents being either introduced thereto through the other pair of nozzles ||3 in the forinof a hydrocarbon iluid, or being formed as the result of reactions within the apparatus as described above. This additional combustion serves,y when necessary, to further raise the temperature of the ore to the point required for reduction.

The modified form of apparatus shown in Fig. 9, comprises three successive furnaces or heating units in which the treatment of the ore is carried out; a rotary kiln |3|, a reducing furnace |32, and an electric furnace |33. The rotary kiln |3| is similar to the kiln shown in Fig. 1, and is similarly provided with upper and lower end housings |34 and |35, stack |36, ore supply means |31, and burner means |38. The interior of said kiln constitutes an ore preheating chamber. At the lower end of the kiln the ore is discharged therefrom through an inclined chute Mil/into the upper end of the reducing furnace |32.

The furnace |32 comprises an inner housing |39, and an outer housing MI. The construction of this furnace is shown more fully in Figs. 10 and 12. The inner housing |39 is generally similar to that shown at 3| in Fig. 4, but is shown as being of somewhat greater height in proportion to its diameter. It is ofvcylindrical cross-section throughout the major portion of its height, and is provided with a conical bottom portion |42. and is closed at ite upper end to denne therewithin a completely enclosed vertically extending reducing chamber |48, in `which a vertically extending body of ore is continually maintained during operation of the process, as indicated at |44 in' Fig. 9. Means are provided for excluding atmospheric air from chamber |48, for admitting hydrocarbon fluid thereto under suitable pressure, and for maintaining a pressure therein somewhat above atmospheric pressure,

as described more fully hereinafter.

The outer housing |4|, isgenerally similar to that shown at 39 in Fig. 4, whereby an annular furnace chamber |45 is provided, surrounding the reducingl chamberv |43 throughout the major portion of its height. It is provided, as before, with burner openings |48 and burner means |41, arranged in the same manner as those shown at 44 and 45 in Fig. 4.

The inner housing |59 is provided at its upper end with hopper means |48, for conducting ore from chute |48 into the reducing chamberv |43, and suitable means are provided for controlling the movement of ore through said hopper means. Said control means is shown as arranged -to provide for intermittent charging of ore into the reducing chamber, and may for example, be comparable to the double bell or cone arrangement commonly used for controlling the supply of materials into a blast furnace. In the form of apparatus shown in Fig. l2, the hopper |43.` has an f upper hopper compartment |48a communicating with the lower end of chute |40, and a lower `hopper compartment |48b communicating with chamber |48, through a central opening |49 in the top wall of the inner housing |39,'the upper and lower compartments communicating with each other through an opening 15|. Hopper |48 is located centrallywithin an upward extending portion |52 of the furnace housing, and thesurrounding space |45a constitutes an upward extension of the furnace chamber |45,` for heating materialk within the'hopper. The housing portion |52, is provided with a top wall |158` closing the yupper end of space |45a. Conical valves or lgates |54 and |55, are disposed 'adjacent openings |5| and |49, respectively, and these cones are r,shown as mounted on a centrally located vertical pipe |56, which is in turn supported at its upper end by ari operating lever |51, whereby both cones vmay be raised to closed position, as shown, and may be lowered to positions removed from the hopper openings to permit downward mov l chamber |12, and provided at one en-d with burner gases from laid chamber into said compartment, as described hereinafter.

An inclined conduit or chute |85 leads from the bottom ofthe reducing chamber. for conducting treated ore therefrom. and charging it into the electric furnace |38, and said conduit may be provided with a gate valve |88 or other suitable means, for normally retaining the ore in the reducing chamber, and intermittently charging the electric furnace. The electric furnace |33 is similar in construction and mode of operation to that shown at 4 in Fig. 1, the means for discharging molten metal and slag therefrom being indicated diagrammatically at |61 and |88. The fluid preheating means is indicated at I1 It may be of the same construction and arran-gement as the preheater 8| described above. but I have shown in this case a somewhat different construction, comprising a refractory lined cylindrical furnace housing deilning a combustion means |13. 'I'he hot combustion gases are discharged from furnace |1|l at the other end.

through a plurality of conduits or ues- |14, communicating with the furnace chamber |45, at positions spaced 90 apart, and midway between the burner openings |48, as indicated at |15 in ment of ore. Pipe |56 also serves to conduct gasesfrom the upper end of the reducing cham--` ber |43 to the burner means |88. Said pipe is open at its lower end, in communication with chamber |43. It extends slidably through burner means |38, and is provided with a nozzle or opening |58 within the burner, ,for delivering gas thereto, and is closed at its upper end.

Additional combustible gas or other fuel may be supplied to burner means |38 through pipe |59. Pipes and |59, are shown provided with valves |8| and |62 for controlling flow therethrough.

Means are provided for conducting hot combustion gases from the furnace chamber |45, of reducing furnace |32 into the rotary kiln |3|, and such rmeans is shown as comprising .the upper hopper compartment |48aand chute |40, said compartment communicating with 'space' |li5a Fig. l0.

Ten separate heating coils extend longitudinally within the combustion chamber |12, as indicated at |18, and are mounted on suitable ref fractory supporting means |11. The respective heating coils are connected through separate pipe's |18, to a common fluid supply line |19, each of the pipes |18 being provided with a valve |8|, for regulating the supply of hydrocarbon fluid to the respective heating coils.

The means for supplying heated hydrocarbon iiuid to the vreducing chamber |43, comprises eight pipes |82 similar in construction and arrangement to the pipes 95 described above, and provided at their upper ends with similar means (as shown in Fig. 7), for introducing iluid into Ithe ore body, and two pipes |83 corresponding to the pipes |01 and |08 in Fig. 4, communicating with separate compartments within a centrally clisposed vertical pipe I84, having upper and lower `sets of nozzles |85 and |88, communicating with the respective compartments, in substantially the same manner as described above in connection with Fig. 4. In lthis case the centrally located pipe |84, is shown as mounted directly on the furnace housing at its lower end, and supported at its upper end by bars |81, secured to the side wall of the inner housing |39.

The above described pipes |82 and |83, enter furnace |1| through the rear wall thereof, and are connected as indicated at |88 in Fig. l1, to the respective heating coils |18. It will be noted that in this case a separate heating coil |18, and

. a separate regulating valve |8|, is provided for through a plurality of 'openings |63'in lthe Wall of ach of the individual pipes |82 and |83.

In the operation of this form of the apparatus the ore is first dried and preheated in rotary kiln |3|, in `the same manner as described above in connection with the other form of apparatus, the ore being heated therein by direct contact with hot combustion gases from burner |38, and also by hot gases coming from the heating chamber |45, of the reducing chamber |4|.

'I'he rotary kiln is preferably operated continually andthe heated ore is discharged from the lower end thereof through inclined chute `|4|| into the upper hopper |48a. At suitable intervals additional quantities of this material are necting the upper portion of the reducing chaml electric furnace; means for supplying ore to said bei to supply hot combustion gases thereto; an

vided with inner and outer housings defining an enclosed vertically extending reducing chamber" within the inner housing in which a bodybfore may be maintained, 'and an annular furnace chamber between the inner and outer housings; means associated with said furnace chamber to supply hot combustion gases thereto; an electric furnace; means for supplying ore t0 said preheating chamber; means for delivering ore from said preheating chamber to the upper portion of saidrreducing chamber, to maintain a body of ore therein; a fluid heater outside said reducing chamber, provided with means for supplying hydrocarbon fluid thereto, and means for heating said fluid; conduit meansy connected vto receive heated fluid from said heater, and communicat` ing with the interior.` of the reducing chamber at a plurality of positions intermediate the height thereof, to deliver said heated fluid 'for partly reducing said v ore; gas-conducting means confrom said preheating chamber to the upper-por-v coil means; conduit means for conducting heated v ingv said combustion chamber4 to "said furnace r furnace, for completion of the reduction., Y

ber'with theore preheating chamber ofthe flrstmentioned furnace, to deliver combustible gases from thea reducing chamber to `said preheating chamberfor combustion; and means for delivering partly reduced ore from the lower end of` said reducing chamber to said electric furnace, forcompletion of the reduction. v 4.` An apparatus for the reduction and recovery of metal `from an ore containing a higher oxideof such metal comprising: a furnace provided with an ore preheating chamber, and with means to maintain combustion oi' fuel to heat the ore in said chamber; a reducing furnace provided` with inner and outer housings defining an enclosed vertically extending reducing chamberr within the inner housing in which abody of ore may be maintained', and an annular furnace chamber between the inner and outer housings; means associated with said furnace chamber to supply` hot combustion gases thereto; gas-conducting means vconnecting the upper portion ofV said furnace chamber to said ore preheating chamber, for conducting hot gases from said fur- X nace chamber to said preheating chamber; an 4l ing zone to deliver said heated fluid rfor partly reducing said ore; and means fondischarge of treated ore fromth'e' lowerend of said reducing ing inner and outer housings deningan'enclos'ed vertically extending reducing chamberfwithin the the reducing chamber through the wall lof'said thereto; means for deliveringore 'to' theupper body of ore therein; a, fluid heater outside said y plying hydrocarbon fluid thereto,'and Vrmeansfor 40 connected to receive heated fluid `from said heatreducingchamber 'at a plurality o'fjpositions inpreheating chamber; means fordelivering ore from said preheating chamber to the upper pcr- Chamber. v tion of said reducing chamber, to maintain a 7. In apparatus for the reduction'and recovery body of ore therein; a fluid heater outside said 50. of a metal from ancre containing a higher oxide reducingchamber, providedwith means for supthereof, a reducing furnace comprising inner and plying hydrocarbon fluid thereto, and means for outer housings defining an enclosed vertically exheating said uid; conduit means connected to tendmg reducing chamber within the inner nousreceive heated fluid fromsaid heater, and commg in which a lbody of ore may bemaintained, mui'iicating with the interior of the reducing 55A and an annular furnace `chamber between the inchamber at a plurality of positions intermediate nel' and 0111581 hOllSingS; meansassociated'with` the height thereof, to deliver said heated fluid for partly reducing said ore; and means for degases thereto; means fOr delivering Ore to theA nvering partly reduced ore from the lower end upper portion 0f said reducing chamber to main-f of said reducing chamber to said electric furnace, tam a ybody of ore therein; a fluid heater outside for completion of thereduction. d

5. An apparatus for the reduction and recovery of metal from an ore containing a higher oxide of such metal comprising: a furnace provided with an ore preheating chamber, and with means to maintain combustion of fuelto heat the ore in said chamber; a reducing furnace provided with inner and outer housingszdeilning an enclosed Yvertically `extending reducing chamber within the inner housing in which a body of ore may maintainedj; and an annular furnace chamber` between tlieinner and guter housings; burner'means associa-ted with said furnacechamsupplying hydrocarbon fluid thereto,l and means for heating said hydrocarbon fluid';vconduit means connected to receive heated fluid from said heatreducing chamber within the lower portion thereof, to deliver said heated fluid for partly reducing said ore; and means for discharge of treated ore from the lower end of said reducing chamber. if v 8. In apparatus for the reduction Vand recovoxide thereof, a reducingfurnace comprising inner and outer housings defining an enclosed'verelectric fd'rnace; means for'supplying ore to said 75 tically extending reducing chamber Withidthe hydrocarbon fluid from said heating'coil means,`

and introducing such heated `fluid. into the' in-"'fv terior of the reducing chamber ata; plurality` of positions intermediate the height thereof,y for partly reducing said ore; conduit'means co'rmectfv reducing chamber, provided with means forsuper, and `communicating with the interior of the termediate the height 'of said vertically extend-4 saidl furnace chamber to supply hot combustion said reducing chamber provided with means for er, and communicating `with the interior of the i preheating chamber; `means for delivering-fore i tion of said reducing chamber, 'to maintain "aff" body of ore therein; a fluid preheaterdeflning la combustion 'chamber located outside" saidreif; ducing chamber, and provided with heating coil` means within said combustion chamber; means j for 'supplying hydrocarbon fluid 'to'said heatingk chamber of the reducing furnaceVV for c'c'mdu'ct-` .'f ing hot gases to said furnace chamber ';A and means for delivering lpartly reduced ore yfromv the' lower end of` said reducing chamber to saidv electric* 6. In apparatus for the reduction" and-r'e'cov"V ery ofr a metal from an ore containing '-a higher" oxide of said metal, a reducing furnace comprisinnerhousing, in which a body fof ore may rb e "f maintained, and an annular furnace chamber bei tween the inner and outer housings'surrounding .the reducing chamber throughout the'major portion of its height, to provide a vertically extending 7 zone in which heat is supplied tothe ore Within inner housing; means associatedfwith saidfurnace chamber to supplyk hot combustin rgases portion of said reducing chamber to Vmaintaina "heating said hydrocarbon fluid;-` conduit means ery of a. metal from an ore containing a higher Y 2,340,346 inner housing in which a body of ore may be maintained, and an annular furnace chamber between the inner and outer housings; means associated with said furnacechamber ito supply hot combustion gases thereoymeans (fordeliverin'g ore to the upper portion of said reducing chamber, to maintain a body of ore-therein; a fluid heater outside said' reducing chamber, provided with means for supplying hydrocarbon fluid thereto, and means for heating said hydrocarbon fluid; a plurality of separate conduits connected to receive-heated fluid from said heater, and communicating respectively with the interior of the sitions intermediate the height thereof, to deliver said heated fluid for partly reducing said ore and each provided with a valve to regulate the flow of fluid therethrough; and means forA dist charge of treated ore from the lower end ofsai reducing chamber. 9. In apparatus for the reduction and recovery of a metal from` an ore containing a higher oxide of said metal, a reducing furnace comprising inner and outer housingsdeflning an enclosed vertically extending reducing chamber within a body of ore therein; a uid `heater outside said reducing chamber, provided with meansffor supreducing chamber at a plurality of different powith` a vertically extending' ore-receiving champlying hydrocarbon fluid thereto, and means for heating said fluid; conduit means connected to receive heated fiuidfrom said heater, and communicating `with the ore-receiving chamber of said auxiliary reducing furnace at a plurality of positions in the lower portion thereof other con-- duit means connected to receive heated fluid from -of said reducing chamber to said electric furnace, for completion of the reduction.

1l. An apparatus for the reduction `and recoveryof metalv from an ore containing a higher oxide of metal comprising: a furnace provided lAber. and with means at its upper end for admitthe inner housing in which a body of ore may l be maintained, and an annular furnace chamber between the inner and outer housings surrounding the reducing chamber throughout the maior portion of its height, to provide a vertically extending zone in which heat is supplied to the ore within the reducing chamber throughthe wail of said inner housing; means associated with said furnace chamber to supply hot combustion gases thereto; means for delivering ore to the upper portion of said reducing chamber to maintain a body of ore therein; a fluid heater outside said reducing chamber, provided with means for supplying hydrocarbon fluid thereto,` and means for heating said hydrocarbon fluid; conduit means connected to receivevheated fluid from said heater, and communicating with the reducing chamber at a plurality of angularly spaced positions l in the lowei` portion of said vertically extending zone, and between the axis and periphery of said reducing chamber; other conduit means connect- `ed to receive heated fluid from said heater, and

communicating with the reducing chamber at a plurality of positions in the central portion of said reducing chamber, and intermediate the height of said vertically extending zone to deliver `said heated fluid for partly reducingsaid' ore;

and means for discharge of treated ore from the lower end of said reducing chamber. A

l0. An apparatus for the reduction and recovery of metal from an ore containing a higher oxide of such metal comprising: a rotary kiln pro-` vided with means to maintain combustion oi' fuel to heat ore therein; an auxiliary reducing furnace having an enclosed ore-receiving chamber, and means for heating ore therein; a main reducing furnace provided with inner. and outer housings defining an enclosed vertically extend` ing chamber within theinner housing in which a body of ore may be maintained, and an annu-` lar furnace chamber between the inner and outer housings; means associated with said furnace chamber to supply hot combustion gases thereto; an electric furnace: means for supplying ore to said rotary kiln; means for delivering ore from said rotary kiln to the ore-receiving chamber of said auxiliary reducing furnace, to maintain a body ofV ore therein: means for delivering ore from said last-mentioned chamber to the upper portionofsaid reducing chamber, to maintain ting air to maintain combustion in the upper portion of said chamber `to heat ore therein; a reducing furnace provided with inner and outer housings defining an enclosed vertically extending reducing chamber within the inner housing l in which a body of ore `may be maintained, and an annular furnace chamber between the inner and outery housings; means associated with said furnace chamber to supply hot combustion gases thereto; an electric furnace; means for supply-4 ing ore to the upper portion of theI ore-receiving chamber of the first-mentioned furnace, to maintain a'body of ore therein; means for delivering orefromthe bottom of said ore-receiving chamber to the upper portion of said reducing chamt ber` to maintain a body of ore therein; a fluid `heater outside said ore-receiving and reducing chamber, provided with means for supplying hy,

drocarbon fluid thereto and means for heating said fluid; conduit means connectedto receive heated fluid from said heater and communicating with the ore-receiving chamber of said nrstmentioned furnace at al' plurality of positions in the lower portion thereof; other conduit means connected to receive heatediiuid from said heater, and communicating with the interior of said reducing chamber at a plurality 0f positions intermediate the height thereof, to deliver said heated fluid for` the partial reduction of said ore in said reducing chamber; means for conducting gas containing combustible constituents from the upper portion of said reducing chamber to said cre-receiving chamber for combustion inthe upper portion thereof, and adjacent saidJair-admittlng means; and means for delivering partly reduced ore from the lower' end of said reducing chamber to said electric furnace, for completion of the reduction.

12. An apparatus for the reduction and recovery of Ymetal from an ore containing a higher oxide of such metal comprising: a rotary kiln provided at its lower end with burner means for f supplying hot combustion gases thereto: a reducing furnace provided with inner and outerA housings defining an enclosed vertically extending reducing chamber within the inner /housing in which a body of ore may be maintained, and a heating chamber between the inner and outer housings; means associated with said heating chamber to supplyhot combustion gases thereto; an electric furnacermeans for supplying ore eeedeee thereof, to deliver seid heated uid for the partiel reduction of seid ore m seid reducing chamber; end means for delivering partly reduced ore from `Moe lower end of seid reducing chamber to seid electric furnace, :for completion of the reduction.

ELFEGO RVEROLL. 

